Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress

Isolated anticyclones are frequently observed below the mixed layer in the Arctic Ocean. Some of these sub-surface anticyclones are thought to originate at surface fronts. However, previous idealized simulations with no surface stress show that only cyclone-anticyclone dipoles can propagate away fro...

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Published in:Journal of Physical Oceanography
Main Authors: Brannigan, L, Johnson, H, Lique, C, Nycander, J, Nilsson, J
Format: Article in Journal/Newspaper
Language:unknown
Published: American Meteorological Society 2017
Subjects:
Arctic
Arctic Ocean
Online Access:https://doi.org/10.1175/JPO-D-17-0022.1
https://ora.ox.ac.uk/objects/uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6
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spelling ftuloxford:oai:ora.ox.ac.uk:uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6 2024-10-06T13:46:26+00:00 Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress Brannigan, L Johnson, H Lique, C Nycander, J Nilsson, J 2017-09-06 https://doi.org/10.1175/JPO-D-17-0022.1 https://ora.ox.ac.uk/objects/uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6 unknown American Meteorological Society doi:10.1175/JPO-D-17-0022.1 https://ora.ox.ac.uk/objects/uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6 https://doi.org/10.1175/JPO-D-17-0022.1 info:eu-repo/semantics/openAccess Journal article 2017 ftuloxford https://doi.org/10.1175/JPO-D-17-0022.1 2024-09-06T07:47:35Z Isolated anticyclones are frequently observed below the mixed layer in the Arctic Ocean. Some of these sub-surface anticyclones are thought to originate at surface fronts. However, previous idealized simulations with no surface stress show that only cyclone-anticyclone dipoles can propagate away from baroclinically unstable surface fronts. Numerical simulations of fronts subject to a surface stress presented here show that a surface stress in the same direction as the geostrophic flow inhibits dipole propagation away from the front. On the other hand, a surface stress in the opposite direction to the geostrophic flow helps dipoles to propagate away from the front. Regardless of the surface stress at the point of dipole formation, these dipoles can be broken up on a timescale of days when a surface stress is applied in the right direction. The dipole breakup leads to the deeper anticyclonic component becoming an isolated sub-surface eddy. The breakup of the dipole occurs because the cyclonic component of the dipole in the mixed layer is subject to an additional advection due to the Ekman flow. When the Ekman transport has a component oriented from the anticyclonic part of the dipole towards the cyclonic part then the cyclone is advected away from the anticyclone and the dipole is broken up. When the Ekman transport is in other directions relative to the dipole axis it also leads to deviations in the trajectory of the dipole. A scaling is presented for the rate at which the surface cyclone is advected that holds across a range of mixed layer depths and surface stress magnitudes in these simulations. The results may be relevant to other regions of the ocean with similar near-surface stratification profiles. Article in Journal/Newspaper Arctic Arctic Ocean ORA - Oxford University Research Archive Arctic Arctic Ocean Journal of Physical Oceanography 47 11 2653 2671
institution Open Polar
collection ORA - Oxford University Research Archive
op_collection_id ftuloxford
language unknown
description Isolated anticyclones are frequently observed below the mixed layer in the Arctic Ocean. Some of these sub-surface anticyclones are thought to originate at surface fronts. However, previous idealized simulations with no surface stress show that only cyclone-anticyclone dipoles can propagate away from baroclinically unstable surface fronts. Numerical simulations of fronts subject to a surface stress presented here show that a surface stress in the same direction as the geostrophic flow inhibits dipole propagation away from the front. On the other hand, a surface stress in the opposite direction to the geostrophic flow helps dipoles to propagate away from the front. Regardless of the surface stress at the point of dipole formation, these dipoles can be broken up on a timescale of days when a surface stress is applied in the right direction. The dipole breakup leads to the deeper anticyclonic component becoming an isolated sub-surface eddy. The breakup of the dipole occurs because the cyclonic component of the dipole in the mixed layer is subject to an additional advection due to the Ekman flow. When the Ekman transport has a component oriented from the anticyclonic part of the dipole towards the cyclonic part then the cyclone is advected away from the anticyclone and the dipole is broken up. When the Ekman transport is in other directions relative to the dipole axis it also leads to deviations in the trajectory of the dipole. A scaling is presented for the rate at which the surface cyclone is advected that holds across a range of mixed layer depths and surface stress magnitudes in these simulations. The results may be relevant to other regions of the ocean with similar near-surface stratification profiles.
format Article in Journal/Newspaper
author Brannigan, L
Johnson, H
Lique, C
Nycander, J
Nilsson, J
spellingShingle Brannigan, L
Johnson, H
Lique, C
Nycander, J
Nilsson, J
Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
author_facet Brannigan, L
Johnson, H
Lique, C
Nycander, J
Nilsson, J
author_sort Brannigan, L
title Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
title_short Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
title_full Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
title_fullStr Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
title_full_unstemmed Generation of sub-surface anticyclones at Arctic surface fronts due to a surface stress
title_sort generation of sub-surface anticyclones at arctic surface fronts due to a surface stress
publisher American Meteorological Society
publishDate 2017
url https://doi.org/10.1175/JPO-D-17-0022.1
https://ora.ox.ac.uk/objects/uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6
geographic Arctic
Arctic Ocean
geographic_facet Arctic
Arctic Ocean
genre Arctic
Arctic Ocean
genre_facet Arctic
Arctic Ocean
op_relation doi:10.1175/JPO-D-17-0022.1
https://ora.ox.ac.uk/objects/uuid:6969a5a4-d022-499d-8815-bb8e70f5c7e6
https://doi.org/10.1175/JPO-D-17-0022.1
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.1175/JPO-D-17-0022.1
container_title Journal of Physical Oceanography
container_volume 47
container_issue 11
container_start_page 2653
op_container_end_page 2671
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